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Disclosed is a device configured for a valve. The valve has a valve structure that is configured to include an outlet body configured to define an outlet. The outlet body is also configured to attach to a melt processing screw of a molding machine. The valve structure is also configured to include a

Disclosed is a device configured for a valve. The valve has a valve structure that is configured to include an outlet body configured to define an outlet. The outlet body is also configured to attach to a melt processing screw of a molding machine. The valve structure is also configured to include an outlet cover configured to selectively close and open the outlet. The device includes a brake configured to decelerate the outlet cover responsive to deceleration of the outlet body, and the decelerating outlet cover maintains the outlet substantially closed.

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The invention claimed is: 1. A device configured for a valve having a valve structure, the valve structure configured to include an outlet body configured to define an outlet, the outlet body also configured to attach to a melt processing screw of a molding machine, the valve structure also configu

The invention claimed is: 1. A device configured for a valve having a valve structure, the valve structure configured to include an outlet body configured to define an outlet, the outlet body also configured to attach to a melt processing screw of a molding machine, the valve structure also configured to include an outlet cover configured to selectively close and open the outlet, the device comprising: a brake configured to decelerate the outlet cover responsive to deceleration of the outlet body, the decelerating outlet cover maintaining the outlet substantially closed during deceleration of the melt processing screw. 2. The device of claim 1, wherein: the molding machine includes: a barrel, and the melt processing screw configured to operate within the barrel; and the outlet body is configured to detachably attach relative to the melt processing screw. 3. The device of claim 2, wherein: the outlet cover defines a slot extending into the outlet cover at least in part; and the brake includes the slot configured to permit the outlet cover to sufficiently flex against and substantially frictionally engage with the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 4. The device of claim 3, further comprising: a wedge configured to fit within the slot. 5. The device of claim 2, wherein: the outlet cover: forms a cylinder presenting a top end, a bottom end and an outer facing surface, defines a melt passageway therethrough extending from the top end to the bottom end, presents an inner facing surface facing the melt passageway, and defines a slot extending from the outer facing surface to the inner facing surface; and the brake includes the slot configured to permit the outlet cover to sufficiently flex against and substantially frictionally engage with the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 6. The device of claim 2, wherein: the outlet cover: forms a cylinder presenting a top end, a bottom end and an outer facing surface, defines a melt passageway therethrough extending from the top end to the bottom end, presents an inner surface facing the melt passageway, and defines a slot extending from the top end to the bottom end; and the brake includes the slot configured to permit the outlet cover to sufficiently expand against and substantially frictionally engage the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 7. The device of claim 2, wherein: the outlet cover includes at least one slot extending between inner and outer circumferential surfaces of the outlet cover and extending between leading and trailing end faces of the outlet cover; and the brake includes a slot configured to permit the outlet cover to sufficiently expand against and substantially frictionally engage the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 8. The device of claim 2, wherein: the brake includes: a latch configured to selectively actuatably latch the outlet cover with the outlet body, and configured to substantially maintain sealing engagement between the outlet and the outlet cover as the outlet body decelerates. 9. The device of claim 2, wherein: the brake includes: interactable threads being disposed on the outlet cover and the outlet body, and being configured to interactively engage the outlet cover with the outlet body responsive to the melt processing screw operating to rotate. 10. The device of claim 2, wherein: the outlet body is a first disk forming a first passageway therein, and is connected to the melt processing screw; the outlet cover is a second disk forming a second passageway therein, and is placed adjacently to the first disk; and the brake includes: a rotatable shaft connected to the outlet cover, and is configured to selectively align the first passageway with the second passageway responsive to selectively rotating the rotatable shaft. 11. The device of claim 10, wherein: the rotatable shaft is coaxially aligned with the melt processing screw. 12. The device of claim 2, wherein: the barrel has a first rate of expansion; the outlet cover has a second rate of expansion; and the brake includes the second rate of expansion being greater than the first rate of expansion, and responsive to a barrel operating temperature range the outlet cover expands to sufficiently frictionally engage the barrel and to sufficiently decelerate the outlet body and substantially maintain sealing engagement between the outlet cover and the outlet. 13. The device of claim 2, wherein: the brake includes the outlet cover configured to substantially frictionally contact the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 14. The device of claim 2, wherein: the brake includes: magnetic means selectively attracting and sealing the outlet cover with the outlet responsive to deceleration of the outlet body. 15. The device of claim 2, further comprising: a stem extending from the outlet body; and a retainer detachably attached to a distal end of the stem so as to facilitate removal of the outlet cover. 16. The device of claim 1, wherein: the molding machine is a thixo molding machine. 17. The device of claim 3, wherein: the slot has a width less than 0.5 mm. 18. The device of claim 3, wherein: the slot has a width of less than 0.25 mm. 19. The device of claim 3, wherein: the slot is formed by wire electric discharge machining (EDM). 20. The device of claim 3, wherein: the slot is formed into a straight-line configuration. 21. The device of claim 3, wherein: the slot has straight segments which meet at right angles to form overlapping portions in the cover. 22. The device of claim 3, wherein: the slot is sinusoidally shaped to form overlapping portions in the cover. 23. A valve, comprising: a valve structure configured to include: an outlet body configured to define an outlet, and to attach to a melt processing screw of a molding machine, and an outlet cover configured to selectively close and open the outlet; and a brake configured to decelerate the outlet cover responsive to deceleration of the outlet body, the decelerating outlet cover maintaining the outlet substantially closed during deceleration of the melt processing screw. 24. The valve of claim 23, wherein: the molding machine includes: a barrel, and the melt processing screw configured to operate within the barrel; and the outlet body is configured to detachably attach relative to the melt processing screw. 25. The valve of claim 24, wherein: the outlet cover defines a slot extending into the outlet cover at least in part; and the brake includes the slot configured to permit the outlet cover to sufficiently flex against and substantially frictionally engage with the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 26. The valve of claim 25, further comprising: a wedge configured to fit within the slot. 27. The valve of claim 24, wherein: the outlet cover: forms a cylinder presenting a top end, a bottom end and an outer facing surface, defines a melt passageway therethrough extending from the top end to the bottom end, presents an inner facing surface facing the melt passageway, and defines a slot extending from the outer facing surface to the inner facing surface; and the brake includes the slot configured to permit the outlet cover to sufficiently flex against and substantially frictionally engage with the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 28. The valve of claim 24, wherein: the outlet cover: forms a cylinder presenting a top end, a bottom end and an outer facing surface, defines a melt passageway therethrough extending from the top end to the bottom end, presents an inner surface facing the melt passageway, and defines a slot extending from the top end to the bottom end; and the brake includes the slot configured to permit the outlet cover to sufficiently expand against and substantially frictionally engage the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 29. The valve of claim 24, wherein: the outlet cover includes at least one slot extending between inner and outer circumferential surfaces of the outlet cover and extending between leading and trailing end faces of the outlet cover; and the brake includes a slot configured to permit the outlet cover to sufficiently expand against and substantially frictionally engage the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 30. The valve of claim 24, wherein: the brake includes: a latch configured to selectively actuatably latch the outlet cover with the outlet body, and configured to substantially maintain sealing engagement between the outlet and the outlet cover as the outlet body decelerates. 31. The valve of claim 24, wherein: the brake includes: interactable threads being disposed on the outlet cover and the outlet body, and being configured to interactively engage the outlet cover with the outlet body responsive to the melt processing screw operating to rotate. 32. The valve of claim 24, wherein: the outlet body is a first disk forming a first passageway therein, and is connected to the melt processing screw; the outlet cover is a second disk forming a second passageway therein, and is placed adjacently to the first disk; and the brake includes: a rotatable shaft connected to the outlet cover, and is configured to selectively align the first passageway with the second passageway responsive to selectively rotating the rotatable shaft. 33. The valve of claim 32, wherein: the rotatable shaft is coaxially aligned with the melt processing screw. 34. The valve of claim 24, wherein: the barrel has a first rate of expansion; the outlet cover has a second rate of expansion; and the brake includes the second rate of expansion being greater than the first rate of expansion, and responsive to a barrel operating temperature range the outlet cover expands to sufficiently frictionally engage the barrel and to sufficiently decelerate the outlet body and substantially maintain sealing engagement between the outlet cover and the outlet. 35. The valve of claim 24, wherein: the brake includes the outlet cover configured to substantially frictionally contact the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 36. The valve of claim 24, wherein: the brake includes: magnetic means selectively attracting and sealing the outlet cover with the outlet responsive to deceleration of the outlet body. 37. The valve of claim 24, further comprising: a stem extending from the outlet body; and a retainer detachably attached to a distal end of the stem so as to facilitate removal of the outlet cover. 38. The valve of claim 23, wherein: the molding machine is a thixo molding machine. 39. The valve of claim 25 wherein: the slot has a width less than 0.5 mm. 40. The valve of claim 25, wherein: the slot has a width of less than 0.25 mm. 41. The valve of claim 25, wherein: the slot is formed by wire electric discharge machining (EDM). 42. The valve of claim 25, wherein: the slot is formed into a straight-line configuration. 43. The valve of claim 25, wherein: the slot has straight segments which meet at right angles to form overlapping portions in the outlet cover. 44. The valve of claim 25, wherein: the slot is sinusoidally shaped to form overlapping portions in the outlet cover. 45. A molding machine, comprising: a melt processing screw; and a valve, including: a valve structure configured to include: an outlet body configured to define an outlet, and to attach to the melt processing screw, and an outlet cover configured to selectively close and open the outlet; and a brake configured to decelerate the outlet cover responsive to deceleration of the outlet body, the decelerating outlet cover maintaining the outlet substantially closed during deceleration of the melt processing screw. 46. The molding machine of claim 45, wherein: the molding machine includes a barrel; and the melt processing screw is configured to operate within the barrel; and the outlet body is configured to detachably attach relative to the melt processing screw. 47. The molding machine of claim 46, wherein: the outlet cover defines a slot extending into the outlet cover at least in part; and the brake includes the slot configured to permit the outlet cover to sufficiently flex against and substantially frictionally engage with the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 48. The molding machine of claim 47, further comprising: a wedge configured to fit within the slot. 49. The molding machine of claim 46, wherein: the outlet cover: forms a cylinder presenting a top end, a bottom end and an outer facing surface, defines a melt passageway therethrough extending from the top end to the bottom end, presents an inner facing surface facing the melt passageway, and defines a slot extending from the outer facing surface to the inner facing surface; and the brake includes the slot configured to permit the outlet cover to sufficiently flex against and substantially frictionally engage with the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 50. The molding machine of claim 46, wherein: the outlet cover: forms a cylinder presenting a top end, a bottom end and an outer facing surface, defines a melt passageway therethrough extending from the top end to the bottom end, presents an inner surface facing the melt passageway, and defines a slot extending from the top end to the bottom end; and the brake includes the slot configured to permit the outlet cover to sufficiently expand against and substantially frictionally engage the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 51. The molding machine of claim 46, wherein: the outlet cover includes at least one slot extending between inner and outer circumferential surfaces of the outlet cover and extending between leading and trailing end faces of the outlet cover; and the brake includes a slot configured to permit the outlet cover to sufficiently expand against and substantially frictionally engage the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 52. The molding machine of claim 46, wherein: the brake includes: a latch configured to selectively actuatably latch the outlet cover with the outlet body, and configured to substantially maintain sealing engagement between the outlet and the outlet cover as the outlet body decelerates. 53. The molding machine of claim 46, wherein: the brake includes: interactable threads being disposed on the outlet cover and the outlet body, and being configured to interactively engage the outlet cover with the outlet body responsive to the melt processing screw operating to rotate. 54. The molding machine of claim 46, wherein: the outlet body is a first disk forming a first passageway therein, and is connected to the melt processing screw; the outlet cover is a second disk forming a second passageway therein, and is placed adjacently to the first disk; and the brake includes: a rotatable shaft connected to the outlet cover, and is configured to selectively align the first passageway with the second passageway responsive to selectively rotating the rotatable shaft. 55. The molding machine of claim 54, wherein: the rotatable shaft is coaxially aligned with the melt processing screw. 56. The molding machine of claim 46, wherein: the barrel has a first rate of expansion; the outlet cover has a second rate of expansion; and the brake includes the second rate of expansion being greater than the first rate of expansion, and responsive to a barrel operating temperature range the outlet cover expands to sufficiently frictionally engage the barrel and to sufficiently decelerate the outlet body and substantially maintain sealing engagement between the outlet cover and the outlet. 57. The molding machine of claim 46, wherein: the brake includes the outlet cover configured to substantially frictionally contact the barrel responsive to the melt processing screw operating to pressurize melt disposed adjacent to the outlet cover. 58. The molding machine of claim 46, wherein: the brake includes: magnetic means selectively attracting and sealing the outlet cover with the outlet responsive to deceleration of the outlet body. 59. The molding machine of claim 46, further comprising: a stem extending from the outlet body; and a retainer detachably attached to a distal end of the stem so as to facilitate removal of the outlet cover. 60. The molding machine of claim 45, wherein: the molding machine is a thixo molding machine. 61. The molding machine of claim 47, wherein: the slot has a width less than 0.5 mm. 62. The molding machine of claim 47, wherein: the slot has a width of less than 0.25 mm. 63. The molding machine of claim 47, wherein: the slot is formed by wire electric discharge machining (EDM). 64. The molding machine of claim 47, wherein: the slot is formed into a straight-line configuration. 65. The molding machine of claim 47, wherein: the slot has straight segments which meet at right angles to form overlapping portions in the outlet cover. 66. The molding machine of claim 47, wherein: the slot is sinusoidally shaped to form overlapping portions in the outlet cover.